AbstractThe classical bounds on the truncation error of quadrature formulas obtained by Peano's Theorem are revisited, by assuming slightly stronger regularity conditions on the integrand function. The resulting series expansion of the error can be useful when studying the asymptotic complexity of automatic quadrature algorithms. New constants, related to the classical error coefficients are tabulated for the most common symmetric interpolatory rules
The purpose of this paper is to point out essential consideration for com-puting tight bounds for th...
Theoretical and practical aspects of truncation error estimation for Newton–Cotes quadrature formula...
AbstractLet Rn be the error functional of a quadrature formula Qn on [−1,1] using n nodes. In this p...
The classical bounds on the truncation errorofquadrature formulas obtained by Peano's Theorem are re...
AbstractThe classical bounds on the truncation error of quadrature formulas obtained by Peano's Theo...
AbstractFor symmetric quadrature formulas, sharper error bounds are generated by a formulation of th...
We present a unified way to obtain optimal error bounds for general interpolatory integration rules....
AbstractThe computational cost of automatic quadrature programs is analyzed under the hypothesis of ...
AbstractFor symmetric quadrature formulas, sharper error bounds are generated by a formulation of th...
AbstractThe computational cost of automatic quadrature programs is analyzed under the hypothesis of ...
A theoretical error estimate for quadrature formulas, which depends on four approximations of the in...
The corrected quadrature rules are considered and the estimations of error involving the second deri...
We study the error of Gauss-Turan quadrature formulae when functions which are analytic on a neighbo...
We discuss the question, under which conditions Proinov's upper bound for the quadrature error ...
For a large class of quadrature formulas, we derive error bounds in terms of fractional derivatives ...
The purpose of this paper is to point out essential consideration for com-puting tight bounds for th...
Theoretical and practical aspects of truncation error estimation for Newton–Cotes quadrature formula...
AbstractLet Rn be the error functional of a quadrature formula Qn on [−1,1] using n nodes. In this p...
The classical bounds on the truncation errorofquadrature formulas obtained by Peano's Theorem are re...
AbstractThe classical bounds on the truncation error of quadrature formulas obtained by Peano's Theo...
AbstractFor symmetric quadrature formulas, sharper error bounds are generated by a formulation of th...
We present a unified way to obtain optimal error bounds for general interpolatory integration rules....
AbstractThe computational cost of automatic quadrature programs is analyzed under the hypothesis of ...
AbstractFor symmetric quadrature formulas, sharper error bounds are generated by a formulation of th...
AbstractThe computational cost of automatic quadrature programs is analyzed under the hypothesis of ...
A theoretical error estimate for quadrature formulas, which depends on four approximations of the in...
The corrected quadrature rules are considered and the estimations of error involving the second deri...
We study the error of Gauss-Turan quadrature formulae when functions which are analytic on a neighbo...
We discuss the question, under which conditions Proinov's upper bound for the quadrature error ...
For a large class of quadrature formulas, we derive error bounds in terms of fractional derivatives ...
The purpose of this paper is to point out essential consideration for com-puting tight bounds for th...
Theoretical and practical aspects of truncation error estimation for Newton–Cotes quadrature formula...
AbstractLet Rn be the error functional of a quadrature formula Qn on [−1,1] using n nodes. In this p...
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